Okay, so the C# Language Specification has a special section (old version linked) on the Color Color rule where a member and its type has the same name. Well-known guru Eric Lippert once blogged about it.

The question I am going to ask here is in a sense (not) quite the same that was asked in the thread Circular definition in a constant enum. You can go and upvote that other question if you like.

Now for my question. Consider this code:

namespace N
    public enum Color

    public class C1
        public const Color Color = Color.Brown;  // error CS0110 - WHY? Compiler confused by Color Color?
    public class C2
        public static readonly Color Color = Color.Brown;  // fine
    public class C3
        public static Color Color = Color.Brown;  // fine
    public class C4
        public Color Color = Color.Brown;  // fine

The point here is that in each situation above, the right-most identifier Color can refer either to the enum type, or to the class member with the same name. But the Color Color rule mentioned above means that we should see if the member (Brown) is static or non-static. Since it is static in this case, we should interprete Color accordingly.

My obvious main question: Why does this not work with a const type member? Is this unintended?

(Obviously, saying N.Color.Brown (N is the namespace) "fixes" it; I am not asking about that!)

Side note: With local variable const, the above anomaly does not exist:

    public class C5
        public Color Color;
        void M()
            const Color Color = Color.Brown;  // works (no warning for not using local variable?)
    public class C6
        public Color Color;
        void M()
            const Color other = Color.Brown;  // works (warning CS0219, 'other' not used)
  • And the same problem with a pseudo-enum: class Pseudo { public const Pseudo Brown = null; } class C7 { public const Pseudo Pseudo = Pseudo.Brown; /* error CS0110 */ } Feb 27 '15 at 22:01
  • 2
    Constant expressions are a big deal. Technically the compiler could solve this problem by not yet adding the identifier to the symbol table until the entire statement is parsed. But that affects the quality of the diagnostic for const int bad = bad + 1; Now you'd get "name does not exist", that's not pretty. Feb 27 '15 at 22:27
  • 1
    Googling a little, saw a bug filed on JetBrains for the intellisense comment youtrack.jetbrains.com/issue/RSRP-353104 , would be interesting to see a comment there Mar 2 '15 at 16:33
  • 1
    Which compiler version are you using? I wonder if this is any different with Roslyn (VS2015) vs. earlier versions.
    – Joe White
    Mar 2 '15 at 20:10
  • 5
    I'm guessing it is the same in previous versions. I found this: connect.microsoft.com/VisualStudio/feedback/details/621384/… where it appears to have been reported in 2010, to which Microsoft answered 'Will Not Fix'.
    – DrewJordan
    Mar 2 '15 at 20:26

It is a bug. I am unable to reproduce the problem in CTP 5 of VS 2015, and I think this one should have been fixed as part of the Roslyn rewrite. However, a commenter below notes that they can reproduce it in CTP 6. So I'm not sure what is going on here as far as whether this bug has been fixed or not.

On a personal note: I do not specifically recall if I was tasked with looking into this one when it was first reported back in 2010 but since I did quite a bit of work on the circularity detectors around then, odds are pretty good.

This is far from the only bug there was in the circularity detectors; it would get quite confused if there were nested generic types which in turn had generic base types whose type arguments involved the nested types.

I am not at all surprised that Alex "won't fix"ed this one; I spent quite a long time rewriting the code that did class circularity detection and the change was deemed too risky. All that work was punted to Roslyn.

If you're interested to see how the Color Color binding code works in Roslyn, take a look at the aptly-named method BindLeftOfPotentialColorColorMemberAccess -- I love me some descriptive method names -- in Binder_Expressions.cs.

  • thanks Eric. Was I correct that it was using both definitions at once, and that's why it works until you use const?
    – DrewJordan
    Mar 2 '15 at 22:48
  • @DrewJordan: I don't remember; I'd have to take a look at the code. Your supposition is entirely plausible though. Mar 2 '15 at 22:50
  • @EricLippert I've got a CTP 6 virtual machine, and it's not fixed there.
    – Pharylon
    Mar 3 '15 at 21:34
  • @Pharylon: Weird, I am running CTP 5 here and I cannot reproduce the problem. I'll make a note of it in the text. Mar 3 '15 at 21:44

1) It doesn't work with a const because it's trying to allow both definitions (enum type and class member) at the same time, and so it tries to define itself as a function on itself.

2) Is it unintended? sort of. It's an unintended consequence to an intended behavior.

Basically, this is a bug that Microsoft acknowledges but has filed as 'Won't Fix', documented on Connect here.

I can't find the 5.0 language spec online (in article or blog form) anywhere but if you're interested, you can download it here. We're interested in page 161, section 7.6.4, Member Access, and it's first section, which is the same section the OP linked to (it was then).

The fact that you can name a member and a type the exact same name (e.g., Color) is something that was explicitly allowed, even though your identifier now has two separate meanings. Here is the spec's language: Identical simple names and type names In a member access of the form E.I, if E is a single identifier, and if the meaning of E as a simple-name (§7.6.2) is a constant, field, property, local variable, or parameter with the same type as the meaning of E as a type-name (§3.8), then both possible meanings of E are permitted. The two possible meanings of E.I are never ambiguous, since I must necessarily be a member of the type E in both cases. In other words, the rule simply permits access to the static members and nested types of E where a compile-time error would otherwise have occurred. For example:

struct Color {  
    public static readonly Color White = new Color(...);    
    public static readonly Color Black = new Color(...);    
    public Color Complement() {...} 
class A {   
    public Color Color;                 // Field Color of type Color    
    void F() {      
        Color = Color.Black;            // References Color.Black static member                       
        Color = Color.Complement();     // Invokes Complement() on Color field  
    static void G() {       
    Color c = Color.White;          // References Color.White static member 

Here's the key part:

both possible meanings of E are permitted. The two possible meanings of E.I are never ambiguous, since I must necessarily be a member of the type E in both cases. In other words, the rule simply permits access to the static members and nested types of E where a compile-time error would otherwise have occurred.

When you define Color Color = Color.Brown, something changes. Since I (Brown) must be a member of E (Color) in both cases (static and not-static), this rule allows you access to both, instead of restricting one due to the current (non-static) context. However, now you've made one of the contexts (your non-static one) a constant. Since it's allowing both, it's trying to define Color.Brown as both the enum and the class member, but there's a problem with it depending on it's own value (you can't have const I = I + 1 for example).

  • I upvoted (mostly because you found the Connect report (link it from this answer even if it is also in your comment to my question)). But how does your answer explain why no error comes with a non-const field (e.g. the C2.Color from the question) while an error comes with a const type member (C1.Color)? Mar 2 '15 at 21:40
  • I'll add the link to this answer. If I'm understanding it correctly, the compiler would throw an error when a member name clashes with a type name, but it's ignored on purpose because both are guaranteed to have the same fields ('I's). The compiler still can't tell the difference between the enum and the member, it just doesn't tell you that it can't and just uses both definitions. Once you define it as a const it still tries to use both, and the member definition makes it a circular reference.
    – DrewJordan
    Mar 2 '15 at 21:54

I am sure it has something to do with the fact that the value of the constant must be deterministic at compile time, but the value of the (static) property will be determined at run-time.

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